Mandrel of coil box

ABSTRACT

A mandrel of a coil box comprises: a cylindrical mandrel body having a center shaft disposed therein and a slot into which a front end portion of a hot bar is inserted; and a guide part which is arranged towards the inside of the mandrel body from a peripheral wall of one side of the slot so as to prevent the cooling and plastic deformation of the front end portion of the bar inserted through the slot.

TECHNICAL FIELD

The present disclosure relates to a mandrel of a coil box, and more particularly, to a mandrel of a coil box for preventing cooling and plastic deformation of a leading end portion of a bar inserted through a slot in the mandrel and reducing the insertion length of the leading end portion.

BACKGROUND ART

FIG. 1 is a view illustrating a rolling apparatus including a coil box 100 in the related art.

Referring to FIG. 1, a continuous casting process is performed using a ladle 5 filled with molten steel refined in a steel making process, a tundish 10 configured to receive the molten steel from the ladle 5 through an injection nozzle connected to the ladle 5 and temporarily store the molten steel, a mold 15 configured to receive the molten steel and initially solidify the molten steel in a predetermined shape, and a plurality of segments 20 disposed below the mold 15 to perform a series of operations for bending or stretching a non-solidified slab while cooling the slab.

In such a continuous casting process, a slab is cooled and reduced while passing through the segments 20. After passing through the segments 20, the slab may be subjected to rough rolling, shearing, and heating by a roughing mill 25, shears 30 and 35, and an inductive heater 40.

The slab may be formed as a bar 1 through such processes and fed to the coil box 100 so as to be coiled or uncoiled.

For example, if coiling or uncoiling in the coil box 100 is delayed, a bar 1, being continuously fed, may be processed as plate scrap by the shears 30 and 35.

A shear 45, a finishing mill 50, a run-out table 55, a final shear 60, and a coiler 70 may be sequentially arranged after the coil box 100 so that the bar 1 discharged from the coil box 100 may be continuously rolled, sheared, and coiled as a coil.

The above-explained processes are examples to which a coil box of the present disclosure may be applied. The coil box of the present disclosure may be used in various steel processing processes.

In a hot direct rolling process, the coil box 100 functions as a buffer to allow a continuous process. The coil box 100 will now be described in more detail with reference to FIGS. 2 to 5.

FIG. 2 is a perspective view illustrating the coil box 100 in the rolling apparatus illustrated in FIG. 1, FIG. 3 is another perspective view illustrating the coil box 100 of FIG. 2, FIG. 4 is a plan view illustrating the coil box 100 of FIG. 2, and FIG. 5 is a cross-sectional view taken along line I-I′ of FIG. 4.

The coil box 100 may coil a roughly-rolled bar 1 and maintain the bar 1 at a constant temperature to reduce temperature and texture differences between the leading and trailing ends of the bar 1.

An introduction unit 112 is installed in front of the coil box 100, and a bar 1 is introduced to the coil box 100 through the introduction unit 112. A leveler 116 is installed behind the coil box 100, and the bar 1 is discharged through the leveler 116.

A carousel 130 may be disposed in the coil box 100 for coiling or uncoiling a bar 1. The carousel 130 may swing mandrels 132 to shift the positions of the mandrels 132. The carousel 130 may be connected to a driving unit 140.

The carousel 130 may include the mandrels 132 and rotating wheels 134.

The mandrels 132 are provided as a pair. One of the mandrels 132 (first mandrel 132) is used to coil a bar 1 introduced to the coil box 100, and the other of the mandrels 132 (second mandrel 132′) is used to uncoil and discharge another bar 1, previously coiled.

After the first mandrel 132 coils a bar 1 and the second mandrel 132′ uncoils a bar 1, the carousel 130 may rotate the rotating wheels 134 using the driving unit 140 to shift the positions of the first and second mandrels 132 and 132′. Then, the first mandrel 132 around which the bar 1 is coiled uncoils the bar 1, and the second mandrel 132′ around which no bar 1 is coiled coils a newly-introduced bar 1.

In this manner, the carousel 130 shifts the positions of the first and second mandrels 132 and 132′ to shift coiling and uncoiling and thus to allow for continuous processing.

Motors 136 may be connected to the first and second mandrels 132 and 132′ to rotate the first and second mandrels 132 and 132′, and decelerators 138 may be connected to the first and second mandrels 132 and 132′ to control the rotating speeds thereof.

In the above-described coil box 100, a passage through which a leading end portion of a bar 1 is inserted into the mandrel 132 (hereinafter, the first and second mandrels 132 and 132′ will be collectively referred to as a mandrel 132) for coiling may be precisely tracked and controlled so as to prevent coiling failure and perform a continuous process without interruption.

DISCLOSURE Technical Problem

An aspect of the present disclosure may provide a mandrel of a coil box, the mandrel including a guide part protruding from an edge wall of a slot of the mandrel into the mandrel to prevent a leading end portion of a bar inserted through the slot from making contact with a center shaft, thereby preventing cooling and plastic deformation of the leading end portion and reducing the insertion length of the leading end portion.

Technical Solution

According to an aspect of the present disclosure, a mandrel of a coil box includes: a cylindrical mandrel main body in which a center shaft is disposed, the mandrel main body including a slot to receive a leading end portion of a high-temperature bar; and a guide part formed from an edge wall of the slot toward an inner side of the mandrel main body so as to prevent cooling and plastic deformation of the leading end portion of the bar inserted through the slot.

The guide part may protrude from the edge wall of the slot to prevent the leading end portion of the bar from making contact with the center shaft when the leading end portion of the bar is inserted through the slot.

An inner end of the guide part may be spaced apart from an inner end of an opposite edge wall of the slot by 90 mm to 110 mm.

The guide part may be sloped in a manner such that an inner gap of the slot is smaller than an outer gap of the slot.

An outer end of the guide part may be spaced apart from an outer end of an opposite edge wall of the slot by 200 mm to 300 mm.

The guide part may be formed in one piece with the mandrel main body and may extend from the edge wall of the slot toward the inner side of the mandrel main body.

The guide part may protrude from the edge wall of the slot and taper toward the inner side of the mandrel main body.

A counterweight may be provided on a side of the mandrel main body opposite to the guide part so as not to bias a center of gravity of the mandrel toward the guide part.

Advantageous Effects

As set forth above, according to exemplary embodiments of the present disclosure, the guide part protruding from the edge wall of the slot of the mandrel into the mandrel prevents a leading end portion of a bar inserted through the slot from making contact with the center shaft, thereby preventing cooling and plastic deformation of the leading end portion and reducing the insertion length of the leading end portion.

Therefore, during thin-plate rolling, a tail portion (corresponding to a leading end portion of a bar in mandrel coiling) may have a uniform temperature and thus may not be curled or tangled. Thus, work rolls may not be damaged by a curled or tangled bar, and product quality may not be deteriorated.

In addition, the length of a leading end portion of a bar inserted through the slot into the mandrel may be shortened, and when the bar is coiled around the mandrel, a portion of the bar making contact with the opposite edge wall of the slot may not be easily bent and plastically deformed. That is, deflection of the leading end portion of the bar may be prevented when the bar is coiled, and since the leading end portion is brought into contact with the guide part and supported on the guide part with an appropriate contact force therebetween, initial turns of the bar may be smoothly formed when the bar is coiled around the mandrel. Thus, the coiling process may not be suspended due to initial turn errors.

DESCRIPTION OF DRAWINGS

FIG. 1 is a view illustrating a rolling apparatus including a coil box according to the related art;

FIG. 2 is a perspective view illustrating the coil box of the rolling apparatus illustrated FIG. 1;

FIG. 3 is another perspective view illustrating the coil box of FIG. 2;

FIG. 4 is a plan view illustrating the coil box of FIG. 2;

FIG. 5 is a cross-sectional view taken along line I-I′ of FIG. 4;

FIG. 6 is a view illustrating how the leading end portion of a bar is inserted into a slot of a mandrel and is coiled in the related art; and

FIG. 7 is a view illustrating how the leading end portion of a bar is inserted into a slot of a mandrel of a coil box and is coiled according to an exemplary embodiment of the present disclosure.

FIG. 8 is a view illustrating structural analysis results for different sampling positions.

FIG. 9 is a view illustrating the temperature profile of bars after rolling.

BEST MODE

First, with reference to FIG. 6, an explanation will be given of how a leading end portion 1 a of a bar 1 is inserted into a slot 132 a of a mandrel 132 and is coiled in the related art.

FIG. 6 is a view illustrating how the leading end portion 1 a of the bar 1 is inserted into the slot 132 a of the mandrel 132 and is coiled in the related art.

Referring to FIG. 6, the bar 1, heated to a high temperature and having a thickness of 16 mm to 23 mm, is coiled in the mandrel 132 as follows. The leading end portion 1 a of the bar 1 is inserted into the mandrel 132 through the slot 132 a (having a gap of 310 mm) by a length of about 800 mm to 1,000 mm. Then, the leading end portion 1 a of the bar 1 is brought into contact with a center shaft 133 of the mandrel 132, and as the mandrel 132 rotates, the leading end portion 1 a is brought into contact with an opposite edge wall 132 c of the slot 132 a. Then, the leading end portion 1 a is bent at a position making contact with the opposite edge wall 132 c and brought into contact with the outer surface of the mandrel 132. In this manner, an initial inner turn of the bar 1 is formed and the bar 1 is coiled.

The center shaft 133 is disposed in the mandrel 132 to support the mandrel 132 placed in a coil box having a high temperature (1,100° C.), and coolant flows in the center shaft 133.

Although the center shaft 133 is coated with an insulator having a triple structure, the leading end portion 1 a (about 800 mm to 1,000 mm) of the bar 1, inserted in the mandrel 132 and making contact with the center shaft 133, is inevitably cooled because temperature around the center shaft 133 is about 650° C. due to the influence of coolant flowing in the center shaft 133.

Furthermore, during finishing rolling, a cooled portion of the bar 1 may be rolled at a temperature lower than an Ar3 transformation point to cause structural failures and texture errors, and during thin-plate rolling, a tail portion may have a non-uniform temperature and thus may be curled or tangled. Such failures or defects may damage work rolls to result in product quality deterioration and even workplace accidents such as roll breakage. The above-mentioned tail portion may correspond to the leading end portion 1 a of the coiled bar 1. That is, during uncoiling, the leading end portion 1 a becomes a tail portion.

In a finishing rolling process, it may be important to maintain the entire length and width of a hot-rolled coil at a uniform finishing mill delivery temperature (FDT) equal to or higher than an Ar3 transformation point (870° C.)

However, when a bar 1 is processed by a finishing mill (FM), the tail of the bar 1 (a leading end portion in a mandrel coiling process) enters the FM in a state in which the tail has a temperature lower than that of the other normal part of the bar 1 by about 100° C. because the structure of the mandrel 132 used to coil the bar 1. When the tail exits the FM, the tail has a temperature of 800° C. or lower. Therefore, the bar 1 processed by the FM may not satisfy properties required of steel sheets.

So as not to deliver such defective products to customers, defective portions of the products are removed before packaging. However, this lowers the process yield.

Specific examples showing effects of such temperature decreases are listed in Table 1.

TABLE 1 [Sampling positions and texture test results] Elongation Sampling positions range FDT Standards (skin-pass top portion) Lower Upper (minimum) HS5282601 JS-SPHC 0 m 5 m 10 m 15 m 20 m limit limit 822° C. Analysis TS 408 418 393 401 391 270 — results YP 322 321 290 291 279 — (3, 1t) EL 24 25 30 34 34 27 — * FDT: Finishing Mill Delivery Temperature (temperature of bar 1 after finishing rolling).

A relatively low-temperature portion of a coil corresponding to the tail of a bar 1 in a skin pass rolling process (the tail was a leading end portion in a mandrel coiling process) was sampled at intervals of 5 m, and mechanical properties of the samples were measured in a length direction thereof. Samples collected within 5 m from the end of the tail did not satisfy the lower limit of a target range of elongation. The results of texture defects are shown in Table 1.

In addition, the structures of the samples were analyzed as shown in FIG. 8, and mixed-grain structures were observed until about 20 m. Therefore, in the related art, a leading end portion 1 a (about 800 mm to 1,000 mm) of a bar 1 inserted in the mandrel 132 is cut off because the leading end portion 1 a causes texture defects. For example, before collecting quality test samples from a coil, the sampling length is calculated based on the thickness of the coil so as to fully detect and remove defective portions.

Therefore, an intermediate inspector or an operator of a skin pass mill may be overburdened, and a skin pass rolling process may be additionally performed. In addition, the yield of the skin pass rolling process may be lowered because defective portions are cut off.

A bar 1 is coiled using the mandrel 132 as follows. A leading end portion 1 a of the bar 1 is inserted into the mandrel 132 through the slot 132 a of the mandrel 132, and then the leading end portion 1 a is supported on the center shaft 133 and the opposite edge wall 312. Therefore, as the mandrel 132 is rotated, the leading end portion 1 a is bent, and an initial turn of a coil is formed.

At this time, the bar 1 may receive a force (F) and torque expressed as follows: torque=force (F)×length (L) where the length (L) is a distance between a point of action and a rotation center. As the length (L) increases, the bar 1 may be bent by a smaller force. Therefore, the bar 1 may be easily bent and plastically deformed. That is, in the mandrel 132, the bar 1 may be plastically bent at a portion between the center shaft 133 and the opposite edge wall 312 of the slot 132 a, and thus equilibrium of forces may collapse due to plastic deformation of the bar 1.

In the worst case, initial turns of a coil may be defectively formed due to deflection, and a coiling process may be frequently suspended. Therefore, a mandrel having an improved structure may be required.

A mandrel 300 of a coil box improved according to the present disclosure will now be described in comparison with the mandrel 132 of the related art shown in FIG. 6.

FIG. 7 is a view illustrating how a leading end portion 1 a of a bar 1 is inserted into a slot 310 c of the mandrel 300 and is coiled according to an exemplary embodiment of the present disclosure.

Referring to FIG. 7, the mandrel 300 includes a mandrel main body 310 in which the slot 310 c is formed, and a guide part 320 formed on an edge wall 311 of the slot 310 c of the mandrel main body 310.

A center shaft 200 is disposed in the mandrel main body 310, and the slot 310 c is formed in the mandrel main body 310 to receive the leading end portion 1 a of the bar 1. Coolant flows in the mandrel 300, and thus the temperature of the mandrel 300 is lower than the bar 1 having a high temperature.

The guide part 320 is formed from the edge wall 311 of the slot 310 c toward an inner side of the mandrel main body 310 so as to prevent cooling and plastic deformation of the leading end portion 1 a of the bar 1 inserted through the slot 310 c.

The guide part 320 may protrude from the edge wall 311 of the slot 310 c so as to prevent the leading end portion 1 a of the bar 1 from making contact with the center shaft 200 when the leading end portion 1 a of the bar 1 is inserted through the slot 310 c.

Owing this structure, when the leading end portion 1 a of the bar 1 is inserted, the leading end portion 1 a is not brought into contact with the center shaft 200 having a relatively low temperature and thus is not cooled to a temperature lower than a proper temperature.

Therefore, during thin-plate rolling, a tail portion (corresponding to a leading end portion of a bar in mandrel coiling) may have a uniform temperature and thus may not be curled or tangled. Thus, work rolls may not be damaged, and product quality may not be deteriorated.

In addition, since the leading end portion 1 a of the bar 1 is inserted through the slot 310 c by a length of about 400 mm to about 500 mm shorter than an insertion length of about 800 mm to about 1,000 mm in the related art, and thus when the bar 1 is coiled around the mandrel 300, a portion of the bar 1 making contact with the opposite edge wall 312 of the slot 310 c may not be easily bent and plastically deformed.

That is, when the bar 1 is coiled, the leading end portion 1 a of the bar 1 inserted into the slot 310 c may not undergo deflection but may make contact with the guide part 320 with an appropriate contact force therebetween. Therefore, initial inner turns of the bar 1 may be smoothly formed around the mandrel 300, and thus the coiling process may not be suspended due to defective initial inner turns.

For example, the inner end of the guide part 320 is spaced apart from the inner end of the opposite edge wall 312 of the slot 310 c by a distance of 90 mm to 110 mm. Since the guide part 320 protrudes until the guide part 320 is spaced apart from the inner end of the opposite edge wall 312 by the distance, when the leading end portion 1 a of the bar 1 is inserted in the slot 310 c, the leading end portion 1 a does not make contact with the center shaft 200. In addition, when the bar 1 is coiled around the mandrel 300, a portion of the bar 1 making contact with the opposite edge wall 312 may not be easily bent and plastically deformed.

The guide part 320 may be sloped in a manner such that an inner gap (inner width) of the slot 310 c is smaller than an outer gap (outer width) of the slot 310 c.

That is, since the outer gap of the slot 310 c is greater than the inner gap of the slot 310 c, the bar 1 may be easily inserted into the slot 310 c, and the guide part 320 may stably guide the insertion of the bar 1 into the slot 310 c.

In addition, since the guide part 320 is disposed in the mandrel main body 310 and narrows the inner gap of the slot 310 c, when the leading end portion 1 a of the bar 1 is inserted, the leading end portion 1 a may be prevented from making contact with the center shaft 200.

For example, the outer end of the guide part 320 may be spaced apart form the outer end of the opposite edge wall 312 by a distance of 200 mm to 300 mm, and in this case, the guide part 320 may more effectively function as an insertion guide.

In addition, the guide part 320 may be formed in one piece with the mandrel main body 310 and may extend from the edge wall 311 of the slot 310 c into the mandrel main body 310.

The leading end portion 1 a of the bar 1 inserted in the mandrel main body 310 may be cooled by the center shaft 200, close to the leading end portion 1 a. However, since the guide part 320 formed in one piece with the mandrel main body 310 makes contact with the leading end portion 1 a of the bar 1 in the mandrel main body 310, the leading end portion 1 a may be maintained at an appropriate temperature in the mandrel main body 310.

That is, the leading end portion 1 a of the bar 1 may receive heat from the other high-temperature portion of the bar 1 coiled around the mandrel main body 310 through the mandrel main body 310 and the guide part 320 formed in one piece, and thus the leading end portion 1 a may be maintained at a high temperature.

For example, the guide part 320 may protrude from the edge wall 311 of the slot 310 c and taper toward the inside of the mandrel main body 310. In this case, although the guide part 320 may transfer heat through a wide area thereof, the guide part 320 may not make contact with the center shaft 200.

In addition, counterweights 330 may be formed on a side of the mandrel main body 310 opposite to the guide part 320 so as not to bias the center of gravity of the mandrel 300 toward the guide part 320.

In FIG. 7, the counterweights 330 protrude from an inner side of the mandrel main body 310. However, the current embodiment is not limited thereto. That is, the number and shape of the counterweights 330 are not limited as long as the counterweights 330 cancel out the weight of the guide part 320.

The mandrel 300 of the embodiment of the present disclosure was applied to a production line, and as shown in a graph below, the finishing mill delivery temperature (FDT) of a leading end portion 1 a of a bar 1 that had been inserted in the mandrel 300 and processed through a finishing rolling process was different as compared to an FDT measured in a product line of the related art. In the graph, the x-axis denotes a bar length, the y-axis denotes bar temperature (° C.), FDT (before improvement) denotes FDT measured according to the related art, FDT (after improvement) denotes FDT measured according to the present disclosure.

As shown in FIG. 9, the FDT of a leading end portion of a bar measured after improvement was higher than the FDT of the leading end portion of a bar measured before improvement by about 40° C. to about 50° C., and the temperature of one or two inner turns of a coil making contact with the outer surface of the mandrel main body 310 was increased by about 10° C. to about 20° C. after improvement. Therefore, according to the present disclosure, a steel sheet or bar may be smoothly and stably rolled in a finishing rolling process.

Therefore, intermediate inspectors may be less burdened when inspecting for texture defects caused by a low temperature at the leading end of a bar, and operators may be less burdened when performing a skin pass rolling process for correcting defects. Furthermore, the yield of a skin pass rolling process may not be lowered due to removal of a defective portion.

In the embodiments of the present disclosure, numerical values of materials such as thickness values of bars are given as exemplary values. That is, the embodiments of the present disclosure are not limited thereto.

As described above, according to the embodiments of the present disclosure, in addition to productivity improvements by qualitative effects such as a decreased insertion length of a bar 1 into the mandrel 300, an increased temperature of inner turns of a bar 1 coiled around the mandrel 300, and an improvement in workpiece passing characteristics in a rolling process, other effects may be obtained such as an increase in the yield of a skin pass rolling process resulted from a decrease of scrap, and a decrease of overproduction by reducing defect rates in a test and a re-test.

Furthermore, since it is not necessary to cut a hot-final workpiece in a skin pass rolling process to remove a portion corresponding to a leading end portion 1 a of a bar 1, costs necessary for the skin pass rolling process may be reduced, and thus manufacturing costs may be markedly reduced.

While exemplary embodiments have been shown and described above, it will be apparent to those skilled in the art that modifications and variations could be made without departing from the spirit and scope of the present disclosure as defined by the appended claims. 

1. A mandrel of a coil box, the mandrel comprising: a cylindrical mandrel main body in which a center shaft is disposed, the mandrel main body comprising a slot to receive a leading end portion of a high-temperature bar; and a guide part formed from an edge wall of the slot toward an inner side of the mandrel main body so as to prevent cooling and plastic deformation of the leading end portion of the bar inserted through the slot.
 2. The mandrel of claim 1, wherein the guide part protrudes from the edge wall of the slot to prevent the leading end portion of the bar from making contact with the center shaft when the leading end portion of the bar is inserted through the slot.
 3. The mandrel of claim 2, wherein an inner end of the guide part is spaced apart from an inner end of an opposite edge wall of the slot by 90 mm to 110 mm.
 4. The mandrel of claim 2, wherein the guide part is sloped in a manner such that an inner gap of the slot is smaller than an outer gap of the slot.
 5. The mandrel of claim 4, wherein an outer end of the guide part is spaced apart from an outer end of an opposite edge wall of the slot by 200 mm to 300 mm.
 6. The mandrel of claim 1, wherein the guide part is formed in one piece with the mandrel main body and extends from the edge wall of the slot toward the inner side of the mandrel main body.
 7. The mandrel of claim 1, wherein the guide part protrudes from the edge wall of the slot and tapers toward the inner side of the mandrel main body.
 8. The mandrel of claim 1, wherein a counterweight is provided on a side of the mandrel main body opposite to the guide part so as not to bias a center of gravity of the mandrel toward the guide part. 